Weighted round robin

Weighted round robin (WRR) is a scheduling algorithm used in networks to schedule data flows, but also used to schedule processes.

Weighted round robin[1] is a generalisation of Round-robin scheduling. It serves a set of queues or tasks. Whereas round-robin cycles over the queues/tasks and gives one service opportunity per cycle, weighted round robin offers to each a fixed number of opportunities, the work weight, set at configuration. It then allow to influence the portion of capacity received by each queue/task.

In computer networks, a service opportunity is the emission of one packet, if the selected queue is non empty. If all packets have the same size, WRR is the simplest approximation of generalized processor sharing (GPS).

There exists several variations of WRR[2]. The main ones are the classicall WRR, and the Interleaved WRR.

Algorithm

Principles

WRR is presented in the following as a network scheduler. It can also be used to schedule tasks in a similar way.

A weighted round-robin network scheduler has $n$ input queues, $q_{1},...,q_{n}$ . To each queue $q_{i}$ is associated $w_{i}$ , a positive integer, called the weight. The WRR scheduler has a cyclic behavior. In each cycle, each queue $q_{i}$ has $w_{i}$ emissions opportunities.

The different WRR algorithms differ on the distributions of these opportunities in the cycle.

Classical WRR

In classical WRR [2][3][4] the scheduler cycles over the queues. When a queue $q_{i}$ is selected, the scheduler will send packets, up to the emission of $w_{i}$ packet or the end of queue.

Constant and variables: 
    const N             // Nb of queues 
    const weight[1..N]  // weight of each queue
    queues[1..N]        // queues
    i                   // queue index
    c                   // packet counter
    
Instructions:
while true do 
   for i in 1 .. N do
      c:= 0
      while (not queue[i].empty) and (c<weight[i]) do
         send( queue[i].head() )
         queue[i].dequeue()
         c:= c+1

Interleaved WRR

Let $w_{max}=\max\{w_{i}\}$ , be the maximum weight. In IWRR [1][5], each cycle is split into $w_{max}$ rounds. A queue with weight $w_{i}$ can emit one packet at round $r$ only if $r\leq w_{i}$ .

Constant and variables: 
    const N             // Nb of queues 
    const weight[1..N]  // weight of each queue
    const w_max
    queues[1..N]        // queues
    i                   // queue index
    r                   // round counter
    
Instructions:

while true do
   for r in 1 .. w_max do 
      for i in 1 .. N do
         if (not queue[i].empty) and (weight[1..N] >= r)then
            send( queue[i].head() )
            queue[i].dequeue()

Example

Example of scheduling for CRR and IWRR

Consider a system with three queues $q_{1},q_{2},q_{3}$ and respective weights $w_{1}=5,w_{2}=2,w_{3}=3$ . Consider a situation where they are 7 packets in the first queue, A,B,C,D,E,F,G, 3 in the second queue, U,V,W and 2 in the third queue X,Y. Assume that there is no more packet arrival.

With classical WRR, in the first cycle, the scheduler first selects $q_{1}$ and transmits the five packets at head of queue,A,B,C,D,E (since $w_{1}=5$ ), then it selects the second queue, $q_{2}$ , and transmits the two packets at head of queue, U,V (since $w_{2}=2$ ), and last it selects the third queue, which has a weight equals to 3 but only two packets, so it transmits X,Y. Immediately after the end of transmission of Y, the second cycle starts, and F,G from $q_{1}$ are transmitted, followed by W from $q_{2}$ .

With interleaved WRR, the first cycle is split into 5 rounds. In the first one (r=1), one packet from each queue is sent (A,U,X), in the second round (r=2), another packet from each queue is also sent (B,V,Y), in the third round (r=3), only queues $q_{1},q_{3}$ are allowed to send a packet ( $w_{1}>=r$ , $w_{2}<r$ and $w_{3}>=r$ ), but since $q_{3}$ is empty, only C from $q_{1}$ is sent, and in the fourth and fifth rounds, only D,E from $q_{1}$ are sent. Then starts the second cycle, where F,W,G are sent.

Task scheduling

Task or process scheduling can be done in WRR in a way similar to packet scheduling: when considering a set of $n$ active tasks, they are scheduled in a cyclic way, each task $\tau _{i}$ gets $w_{i}$ quantum or slice of processor time [6][7].

Properties

Like round-robin, weighted round robin scheduling is simple, easy to implement, work conserving and starvation-free.

When scheduling packets, if all packets have the same size, then WRR is an approximation of Generalized processor sharing[8]: a queue $q_{i}$ will receive a long term part of the bandwidth equals to ${\frac {w_{i}}{\sum _{j=1}^{n}w_{j}}}$ (if all queues are active) while GPS serves infinitesimal amounts of data from each nonempty queue and offer this part on any interval.

If the queues have packets of variable length, the part of the bandwidth received by each queue depends not only on the weights but also of the packets sizes.

If a mean packets size $s_{i}$ is known for every queue $q_{i}$ , each queue will receive a long term part of the bandwidth equals to ${\frac {s_{i}\times w_{i}}{\sum _{j=1}^{n}s_{j}\times w_{j}}}$ . If the objective is to give to each queue $q_{i}$ a portion $\rho _{i}$ of link capacity (with $\sum _{i=1}^{n}\rho _{i}=1$ ), one may set $w_{i}={\frac {\rho _{i}}{s_{i}}}$ .

Limitations and improvements

WRR for network packet scheduling was first proposed by Katevenis, Sidiropoulos and Courcoubetis in 1991 [1], specifically for scheduling in ATM networks using fixed-size packets (cells). The primary limitation of weighted round-robin queuing is that it provides the correct percentage of bandwidth to each service class only if all the packets in all the queues are the same size or when the mean packet size is known in advance. In the more general case of IP networks with variable size packets, in order to approximate GPS the weight factors must be adjusted based on the packet size. That requires estimation of the average packet size, which makes a good GPS approximation hard to achieve in practice with WRR [1].

Deficit round robin is a later variation of WRR that achieves better GPS approximation without knowing the mean packet size of each connection in advance. More effective scheduling disciplines were also introduced which handle the limitations mentioned above (e.g. weighted fair queueing).

References

Katevenis, M.; Sidgiropoulos, S.; Courcoubetis, C. (1991). "Weighted round-robin cell multiplexing in a general-purpose ATM switch chip". IEEE Journal on Selected Areas in Communications. 9 (8): 1265–1279. doi:10.1109/49.105173. ISSN 0733-8716.
Chaskar, H.M.; Madhow, U. (2003). "Fair scheduling with tunable latency: A round-robin approach". IEEE/ACM Transactions on Networking. 11 (4): 592–601. doi:10.1109/TNET.2003.815290. ISSN 1063-6692.
Brahimi, B.; Aubrun, C.; Rondeau, E. (2006). "Modelling and Simulation of Scheduling Policies Implemented in Ethernet Switch by Using Coloured Petri Nets": 667–674. doi:10.1109/ETFA.2006.355373. Cite journal requires |journal= (help)
F. Baker; R.Pan (May 2016). "2.2.2. Round-Robin Models". On Queuing, Marking, and Dropping (Technical report). IETF. RFC 7806.
Semeria, Chuck (2001). Supporting Differentiated Service Classes: Queue Scheduling Disciplines (PDF) (Report). pp. 15–18. Retrieved 4 May 2020.
Beaulieu, Alain (Winter 2017). "Real Time Operating Systems -- Scheduling & Schedulers" (PDF). Retrieved 4 May 2020.
United States 20190266019, Philip D. Hirsch, "Task Scheduling Using Improved Weighted Round Robin Techniques", published 29 August 2019
Fall, Kevin (29 April 1999). "EECS 122, "Introduction to Communication Networks", Lecture 27, "Scheduling Best-Effort and Guaranteed Connections"". Retrieved 4 May 2020.

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[WRR-ATM-1991-1] Katevenis, M.; Sidgiropoulos, S.; Courcoubetis, C. (1991). "Weighted round-robin cell multiplexing in a general-purpose ATM switch chip". IEEE Journal on Selected Areas in Communications. 9 (8): 1265–1279. doi:10.1109/49.105173. ISSN 0733-8716.

[WRR-2003-2] Chaskar, H.M.; Madhow, U. (2003). "Fair scheduling with tunable latency: A round-robin approach". IEEE/ACM Transactions on Networking. 11 (4): 592–601. doi:10.1109/TNET.2003.815290. ISSN 1063-6692.

[CPN-WRR-ETFA06-3] Brahimi, B.; Aubrun, C.; Rondeau, E. (2006). "Modelling and Simulation of Scheduling Policies Implemented in Ethernet Switch by Using Coloured Petri Nets": 667–674. doi:10.1109/ETFA.2006.355373. Cite journal requires |journal= (help)

[RFC-7806-4] F. Baker; R.Pan (May 2016). "2.2.2. Round-Robin Models". On Queuing, Marking, and Dropping (Technical report). IETF. RFC 7806.

[Juniper-Queuing-5] Semeria, Chuck (2001). Supporting Differentiated Service Classes: Queue Scheduling Disciplines (PDF) (Report). pp. 15–18. Retrieved 4 May 2020.

[Beaulieu-Course-6] Beaulieu, Alain (Winter 2017). "Real Time Operating Systems -- Scheduling & Schedulers" (PDF). Retrieved 4 May 2020.

[WRR-Pattent-7] United States 20190266019, Philip D. Hirsch, "Task Scheduling Using Improved Weighted Round Robin Techniques", published 29 August 2019

[kfall-lecture-8] Fall, Kevin (29 April 1999). "EECS 122, "Introduction to Communication Networks", Lecture 27, "Scheduling Best-Effort and Guaranteed Connections"". Retrieved 4 May 2020.